DE3934890A1 - AUTOMATIC ANALYZER - Google Patents

Description

The invention relates to an automatic analyzer and ins special a device for chemical analysis of various sub punch types in a sample liquid, such as a blood sample, with the help of a variety of automatic analysis modules, of which each is able to sample liquid with respect to a or several components or objects to be analyzed analyze, taking samples one by one from the upstream ge side of the modules and selectively to the Reak vessels of the modules.

Such an automatic analyzer, as mentioned above, is already known, for example from the published japa African utility model 53-8544. In this conventional device two to eight analysis modules are arranged in series Sample vessels with the sample liquids to be analyzed Modules are fed one after the other via only one path. The required sample quantities are recorded and sent to Reak tion vessels in the modules taking into account the or components or objects of each to be analyzed Sample and of the component (s) to be analyzed or Ge objects that can be analyzed in each module, submitted. That is, in the conventional device, although it not all components of all analysis modules are necessary to have all samples analyzed one after another on all analy semodules must be passed. In the well-known Vorrich  tion is generally used a conveyor belt to the Pro to carry the receptacles past the analysis modules. Because the number of Objects that are generally analyzed in a module that can be in the range of four to twelve, it is possible Lich, in the automatic analyzer as a whole 20 to 30 Analyze objects. On the other hand, the components whose analysis is required, generally from sample to Sample different. In general, the number of stocks divide only 50 in a sample that requires analysis up to 60% of the possible analysis objects of the device. In in other words, 40 to 50% of the possible analysis objects, whose analysis can be carried out in the device is the not assigned to the respective samples.

As explained above, in the conventional automatic Analyzer one after the other at the Ana lysis modules passed, regardless of the respective test objects ascribed to the samples to be analyzed. So while a sample, its components in one module not be analyzed, the module happens, is in this Module did not perform an analysis of what the process time was before direction extended overall. This disadvantage comes in particular This is expressed when the device contains many samples only need to be analyzed for fewer components, are fed in succession.

The aim of the invention is therefore an automatic analyzer with increased operational efficiency.

This goal is achieved with an automatic analysis device with a sample feeder for the successive feed of sample vessels with the samples to be analyzed by
a plurality of analysis modules, each of which can analyze at least one object to be analyzed and has a sample dispensing device for dispensing samples into the reaction vessels;
a plurality of first paths, in the central part of which an analysis module is arranged;
at least one second path that bypasses at least one analysis module; and
a device for controlling the dispensing of the sample vessels so that each sample vessel supplied from the sample vessel supply device is selectively fed to either one of the first routes or the second route.

In the automatic analyzer according to the invention, the Analysis modules can be arranged in series or in parallel, the Sample vessels depending on the component to be analyzed in the Sample vessel contained sample regardless of the order of sample vessels via the sample vessels device can be supplied to one of the analysis modules. According to a preferred embodiment of the invention direction, a first and a second analysis module become serial arranged, with a bypass for each analysis module in addition to an analysis path, so that the two upstream and downstream sides of the analysis modules via the bypass are connected. Sample vessels are made according to the specified components of the samples to be analyzed and the analyzable components in the module either the bypass or allocated to the analysis route. That is, if a sample is in the first Analysis module does not need to be analyzed, this will be a sample containing sample vessel over the parallel to the first analysis path arranged bypass supplied to the second analysis module. And if a sample does not have to be analyzed in the second module, is a sample vessel containing this sample after the Delivery of the sample in the first module on the downstream side of the second analysis module via the parallel to the analysis path of the second module arranged bypass supplied.

According to a further preferred embodiment of the inventions Analysis device according to the invention are first and second modules arranged in parallel, with a single bypass to Um the first and second modules. In such In a device, the sample vessels are first either  first module or the second module, depending on what is to be analyzed Part of the sample to be analyzed, that in the modules components that can be analyzed and the assignment of the modules Sample vessels supplied. That is, if a sample is only in the he Most or second module needs to be analyzed, is the sampling depending on the component to be examined, only the first or supplied second module. However, if a sample is in both first and second module must be analyzed the sample vessel first to either the first or second analyte supplied semodul, depending on the assignment of the modules. After that it will Sample vessel via the bypass to the upstream side of the Analysis modules transferred back and fed to the other module.

Thus it is with the automatic analysis according to the invention device, all analysis modules efficiently and without time delay desire to operate.

From the accompanying figures that illustrate the invention, demonstrate

Figure 1 is a schematic representation of the basic structure of a first embodiment of the automatic analyzer according to the Invention.

Fig. 2 is a schematic representation showing a partial structure of a second embodiment of the automatic analysis device according to the invention;

Fig. 3 is a schematic illustration that explains the structure of a third embodiment of the automatic analyzer according to the invention;

Fig. 4 is a schematic representation showing the structure of a fourth embodiment of the automatic analyzer according to the invention; and

Fig. 5 is a schematic representation that shows the structure of a fifth embodiment of the automatic analyzer according to the invention.

Fig. 1 is a schematic illustration showing the basic structure of a first embodiment of the automatic analyzer according to the invention. According to this embodiment, two automatic analysis modules 1 , 2 are arranged in series. The first module 1 can analyze the components A to D and the second module 2 the components E to H. Each module comprises a plurality of reaction vessels and a device for supplying samples from the sample vessels to the reaction vessels. In the device, a sampler or sample task 4 is arranged upstream of the analysis module 1 . In the sample application 4 , a multiplicity of sample vessels with samples to be analyzed are arranged in sequence and one after the other are fed to a common path 3 . The sample vessels are fed via the common path 3 to a first sample distributor 5 . In the first distributor 5 , the sample vessels are assigned to a first analysis path 6 or a first bypass 7 which bypasses the first analysis module 1 , depending on the component to be analyzed, which is contained in the sample contained in the sample vessel. The first analysis path 6 is connected to the first module 1 , so that samples contained in the sample vessels can be dispensed into the reaction vessels of the first module, and the bypass 7 with a second sample vessel distributor 8 . That is, in the event that one or more of the components to be analyzed in the sample are to be analyzed in the first module 1 , the sample vessel containing the sample is assigned to the first analysis path 6 , while in the case that one or more of the components are to be analyzed analyzing components of the sample are to be analyzed in the second module 2 , the sample vessel is fed to the first bypass 7 and then to the second module 2 via the second distributor 8 .

The sample vessel supplied to the analysis path 6 is stopped at a first sampling position P ₁ , at which part of the sample contained in the sample vessel is picked up by a sampling device (not shown), which is present on the first module 1 , and is released into its reaction vessels . At the time when the analysis of the sample in the reaction vessel of the first module 1 begins, the sample vessel is supplied to the second sample vessel distributor 8 .

As stated above, the sample vessel guided into the first bypass 7 is fed to the second distributor 8 and allocated to the second module 2 . In the second distributor 8 , the sample vessels supplied from the first analysis path 6 or the first bypass 7 are further divided into a second analysis path 9 or a second bypass 10 , depending on the component of the sample to be analyzed. If the sample has to be analyzed by the second module, the sample vessel is fed to the second analysis path 9 and part of the sample at the sampling position P ₂ is picked up by a sampling device (not shown), which is provided on the second module 2 , and attached to the reaction vessels of the second module 2 delivered. At the time at which the analysis of the sample in the reaction vessel of the second module 2 begins, the sample vessel is fed to a sample vessel distributor 11 . On the other hand, the sample container supplied to the second bypass 10 is also supplied directly to the sample container distributor 11 . The supplied from the second analysis path 9 and the second bypass 10 sample vessels are then supplied from the sample container feeder 11, which is arranged on the current sample container receiver 13, the sample vessel receiver. 13 All operations of all devices, ie the sampler 4 , the first and second sample vessel distributors 5 and 8 , the sample vessel distributor 11 and the sample vessel receiver 13 are controlled by the central control unit CPU 14 in the analyzer. The analysis objects assigned to each sample are stored in the CPU 14 , so that the position of each sample vessel in the row of sample vessels in the sampler 4 is known. For the operation of a readable for the CPU 14 identification tag may be present or the predetermined order in the sampler 4 of the sample vessels in the CPU on each sample vessel are stored fourteenth The analysis results of the analyzes carried out in the first and second modules 1 , 2 are fed to the CPU 14 and stored there, corresponding to the identity of the sample, and are output at a suitable point in time.

The operation of the analyzer is explained below. The Components of sample Nos. 1 to 3 to be analyzed are in Table 1 reproduced.

Table 1

Samples Nos. 1 to 3 are contained in sample vessels and arranged in this order in Sampler 4 . The first sample vessel with the sample No. 1 is fed from the allocator 4 to the general route 3 and then conveyed to the first sample vessel distributor 5 . The components of sample No. 1 to be analyzed are A , C and D , which are to be analyzed by the first analysis module 1 . The first sample vessel is thus fed to the first analysis device 6 and stopped at the first sampling position P ₁ . At position P ₁ , a predetermined amount of sample No. 1 is delivered to reaction vessels in first module 1 , where components A , C and D are analyzed. During the above-mentioned operation, the second sample vessel with sample No. 2 is supplied to the first sample vessel distributor 5 . Since the components F and G of the sample No. 2 to be analyzed are not analyzed by the first analysis module 1 , the second sample vessel is fed to the second sample vessel distributor 8 via the first bypass 7 . Since the components F and G to be analyzed have to be analyzed by the second analysis module 2 , the second sample vessel is allocated to the second analysis path 7 by the second sample vessel distributor 8 . The second sample vessel is on the Pro bennahmeposition P ₂ of the second analysis module 2 in position ge introduced and removed, a predetermined amount of Sample Nos. 2 and discharged into reaction vessels of the second module 2, then where the components F and G are analyzed. While sample No. 2 is being dispensed to the reaction vessel in the second module 2 , the dispensing of sample No. 1 to the first module 1 has ended and the first sample vessel is being fed to the second distributor 8 . Since the components of the sample No. 1 to be analyzed do not match the analysis objects of the second module 2 , the first sample vessel is fed to the second bypass 10 and transported directly to the sample receiver 13 via the sample vessel distributor 11 and the general route 12 . If the samples No. 1 and 2 are each delivered to the first and second modules 1 , 2 , the third sample vessel containing the samples No. 3 is fed from the sampler 4 to the first sample distributor 5 . Since the constituents to be analyzed of samples 3 A , B and E are, the sample vessel is first assigned to the first analysis path 6 . The third sample vessel is then stopped at the Probennah meposition P ₁ and a predetermined amount of Sample Nos. 3, which is required for the analysis with respect to the constituents A and B, taken out and discharged into reaction vessels of he most module 1. At the end of the dispensing operation of the sample No. 3 in the first module 1 , the dispensing of the sample No. 2 in the second module 2 is ended and the second sample vessel is fed to the sample receiver 13 via the sample distributor 11 and the general path 12 .

After completion of the delivery of samples No. 3 in the first module for the analysis of components A and B , the third sample vessel is fed to the second sample vessel distributor 8 . Since sample No. 3 is assigned to the second module 2 for the analysis of the component E , the third sample vessel is assigned to the second analysis path 9 . The third sample vessel is stopped at the sampling position P ₂ and a predetermined amount of the sample No. 3, which is required for the analysis of the component E , is removed and released into a reaction vessel of the second module 2 . After completion of the delivery of samples No. 3 in the second module, the third sample vessel is transported via the sample vessel divider 11 and the general route 12 to the sample recipient 13 .

As stated above, in this first embodiment the automatic analyzer according to the invention since for each Analysis module is bypassed through the sample vessel the bypass past the module to the Pro located downstream of the module bengefäßverteiler if the sample is not in this Ana lysis module to be analyzed. In this way, the war Reduce the time of a sample vessel on each analysis module be changed and the analysis operation performed more effectively will.

Fig. 2 is a schematic diagram which explains an essential part of the structure of the second embodiment of the automatic analyzer according to the invention. In Fig. 2 the middle part of the overall device is explained. The Analy semodul 21 comprises a first sub-analysis module 21 A and second sub-analysis module 21B. It is possible to design these sub-analysis modules 21 A and 21 B so that the same type of constituent parts can be analyzed in each module, that partially differing constituent parts can be analyzed in each module, or that completely different constituent parts can be analyzed independently can be. The sample vessels supplied from the previous analysis module via the analysis route 22 or a bypass route 23 are via the distributor 24 a first analysis route 25 A , a second analysis route 25 B and a bypass 26 , depending on the components to be analyzed contained in the sample vessels Samples assigned. That is to say, in the event that the component of the sample to be analyzed is to be analyzed in the first sub-analysis module 21 A , the sample vessel is assigned to the first analysis route 25 A , while the sample vessel is assigned to the second analysis route 25 B if the ana lysing component of the sample to be analyzed in the second sub-analysis module 21 B. However, if the component of the sample to be analyzed is not to be analyzed either in the sub-analysis module 21 A or in 21 B , the sample vessel is fed to the module via the bypass 26 . The first sample supplied to the first analysis path 25 A and the second sample supplied to the second analysis path 25 B are transported to the second sample vessel distributor 27 after the delivery of the samples to the two sub-analysis modules 21 A and 21 B has ended . In the second distributor 27 , the sample vessels supplied from the analysis paths 25 A and 25 B or from the bypass 26 are again allocated to the next analysis 28 or the next bypass 29 . As stated above, in the case of arranging a plurality of sub-analysis modules in one analysis module, it is possible to provide a plurality of analysis paths, each of which has a sampling position. In this way it is possible to analyze samples much more efficiently.

In the first and second embodiments, a variety of Analysis modules arranged in series in the analyzer, the Analysis paths and bypass are arranged so that they are mutually run in parallel. There is also a distributor for the feeder the sample vessels on the upstream side of a of each module, and the Be components of the sample and those that can be analyzed in the analysis module Components in the distributor compared. In case that the components of the sample to be analyzed in the analy module the sample vessel is drawn to the analysis path leads, while in the case in which the Be components of the sample should not be analyzed in the module, the sample vessel via the bypass to the next distributor leads. In this way, the sample vessels are the modules allocated efficiently and the samples without waiting handed over to the modules at the withdrawal points.  

Fig. 3 is a schematic diagram showing the structure of a third embodiment of the automatic analyzer according to the invention. In the third embodiment, a first automatic analysis module 31 and a second automatic analysis module 32 are arranged parallel to one another. The first module 31 can analyze the components A to D , while the second module 32 can analyze the components E to H. A sampler 34 is provided in the analysis device, in which a large number of sample vessels with samples to be analyzed are arranged in a predetermined sequence. These sample containers are fed through the sampler 34 one after the other and individually to a general path 36 . The sample container supplied by the sampler 34 is transported via a sample container distributor 35 and a first general path 36 to a sample vessel divider 37 . In the first sample vessel distributor 37 , the sample vessels are allocated to a first or a second analysis path 38 , 39 , depending on the components of the samples contained in the sample containers to be analyzed. That is, if the components of a sample to be analyzed include a component that can be analyzed in the first module 31 , the sample vessel is allocated to the first analysis path 38 and if all components of a sample to be analyzed are to be analyzed in the second module 32 , the sample vessel is assigned to the second analysis path 39 . However, if the components of a sample to be analyzed are to be analyzed by both the first and second modules 31 , 32 , or if the first analysis path 38 connected to the first module 31 is occupied by a sample vessel, the sample vessel becomes the second analysis path 39 assigned.

The sample vessel guided in the first analysis path 38 is stopped at the first sampling position P _{1 of} the first module 31. In the position P ₁ , part of the sample is removed and released into a reaction vessel of the first module 31 . After the analysis of the sample in the reaction vessel has started, the sample vessel is transported further and fed to a second sample vessel distributor 41 via a second general path 42 and a second sample vessel distributor 40 . Correspondingly, the sample vessel is also transported from the second analysis path 39 via a second general path 42 and the second sample vessel distributor 40 to the second distributor 41 after the analysis of the sample in the reaction vessel of the second module 32 has started.

In the second distributor 41 it is evaluated whether the sample in the second module 32 has to be analyzed or not. If the sample supplied from the first analysis path 38 is not to be analyzed in the second module 31 , the sample vessel is fed directly to a sample receiver 44 . If the sample supplied from the first analysis path 38 has to be analyzed further in the second module 32 , the sample vessel is led back to the first sample distributor 37 via a bypass 43 and the first sample distributor 35 . The returned sample is fed from the first distributor 37 into the second analysis path 39 and the sample contained therein is analyzed in the second module 32 .

On the other hand, if the component to be analyzed of the sample supplied from the second analysis path 39 to the second distributor 41 is not to be analyzed in the first module 31 , the sample vessel is fed directly to the sample vessel receiver 44 . However, if the sample in the first module 31 has to be analyzed further, the sample vessel is returned from the second distributor 41 via the bypass 43 to the first distributor 37 and then placed in the first analysis path 38 so that it is analyzed in the first module 31 . A CPU 45 is provided which controls the function of all devices, ie the sampler 34 , the first and second sample distributors 35 , 40 , the first and second sample vessel distributors 37 , 41 , the first and second analysis modules 31 , 32 and the sample vessel receiver 44 .

The sample treatment according to the third embodiment is explained below. It should be noted that the analysis components of samples No. 1 to No. 3 are the same are as shown in Table 1.  

Sample No. 1 is guided by the sampler 34 to the general path 36 and then transported via the first sample container distributor 35 to the first sample container distributor 37 . The components to be analyzed in sample No. 1 are A , C and D , which are to be analyzed in the first module 31 . Therefore, the first sample vessel with the sample No. 1 from the first distributor 37 is allocated to the first analysis path 38 . The first sample vessel is stopped at the sampling position P ₁ and a predetermined amount of the sample No. 1 is picked up and dispensed into reaction vessels installed in the first analysis module 31 . During this operation, the second sample vessel with sample No. 2 is delivered from the sampler 34 to the first sample vessel distributor 37 . The components of sample No. 2 to be analyzed are F and G , which are to be analyzed in the second module 32 . The second sample vessel is therefore fed to the second analysis path 39 and brought into position at the sampling position P _{2 of} the second module 32 . A predetermined amount of sample No. 2 is removed from the sample vessel and released into reaction vessels of the second analysis module 32 . During the operation of the first analysis module 31 , the delivery of sample No. 1 has ended and the sample vessel is felt to the second sample vessel divider 41 . Since the sample No. 1 does not have to be analyzed in the second module 32 , the second distributor 41 allocates the sample vessel to the sample vessel receiver 44 directly via the second sample vessel allocator 40 and the second general route 42 . During the delivery of sample No. 1 in the first analysis module 31 and sample No. 2 in the second analysis module 32 , the third sample vessel with sample No. 3 is delivered from the sampler 34 to the first sample distributor 37 . Since the components to be analyzed of sample No. 3 are A , B and E , the third sample vessel is first assigned to the first analysis 38 . After the delivery of the sample No. 3 for the analysis of the components A and B in the first analysis module 31 , the third sample vessel is delivered to the second sample distributor 41 and is returned to the first sample distributor 37 via the bypass 43 and the first distributor 35 because the inventory Part E is the subject of analysis of Sample No. 3. The third vessel is then fed to the second analysis path 39 for analyzing the component E in the second module 32 . After sample No. 3 has been dispensed in the second module 32 , the third sample vessel is again fed via the second sample vessel dispenser 40 and the general path 42 to the second sample vessel distributor 41 . After completion of the delivery of samples No. 3 in both the first and in the second analysis modules 31 and 32 , the third sample vessel is supplied to the sample vessel receiver 44 .

Fig. 4 is a schematic diagram describing a fourth embodiment of the automatic analyzer according to the invention. In the fourth embodiment, three analysis modules 51 , 52 and 53 are arranged parallel to one another. In the first sample distributor 57 , the sample vessels can be assigned to a first analysis route 58 , a second analysis route 59 or a third analysis route 60 , corresponding to the components to be analyzed in the samples. According to this embodiment, since there are three analysis modules, the objects which can be analyzed in the overall device can be divided into three groups. By selectively distributing the sample vessels, which are supplied from the first sample vessel distributor 55 , on the sample vessels supplied by the sampler 54 and from the second sample vessel distributor 62 via the bypass 64 , sample vessels returned individually to the first sample vessel distributor 57 and from there the first to third analysis path 58 to 60 , it is possible to analyze three samples at the same time, thereby increasing the process capacity of the analyzer as a whole.

Fig. 5 is a schematic diagram showing a fifth embodiment of the automatic analyzer according to the invention. In this embodiment, three analysis modules 71 , 72 , 73 are arranged parallel to one another, as in the fourth embodiment. However, first and second sample vessel distributors 77 A , 77 B are arranged upstream of the analysis modules. At the first distributor 77 A , an analysis path is divided into a first analysis path 78 and a second analysis path 79 A. The second analysis route 79 A is further split at the second distributor 77 B into the extended second analysis route 79 B and a third analysis route 80 . The sample vessels supplied by the sampler 74 are first delivered to the sample vessel distributor 77 A. If the sample contained in the sample vessel is to be analyzed in the first module 71 , the sample vessel is assigned to the analysis path 78 , which is connected to the first module 71 . If the sample is not to be analyzed in the first module, but in the second or third module 72 , 73 , the sample is guided into the second analysis path 79 A , which is arranged between the first and the second distributors 77 A and 77 B and then on delivered the second distributor 77 B. In the second distributor 77 B , the sample vessels are assigned to the extended second analysis path 79 B , which is connected to the second module 72 , or the third analysis path 80 , which is connected to the third module 73 , depending on the components to be analyzed Sample vessel contained sample. The reference number 81 represents a second sample container dispenser, through which the sample containers supplied by the first and second modules 71 , 72 are supplied to a third sample container dispenser 82 . In the third sample container distributor 82 , the sample containers supplied by the third module 73 and by the second distributor 81 are individually fed to a third sample container distributor 83 . If the sample delivered to the third distributor is to be further analyzed in the first, second or third module, the sample vessel is fed to the first distributor 75 via a bypass 84 . Other sample vessels supplied to the third distributor 83 are fed to the sample receiver 85 . In this arrangement of the fifth embodiment of the analysis device, the sample vessels which are to be guided into the second and third analysis modules 72 , 73 wait in the second analysis path 79 A arranged between the first and second distributors 77 A and 77 B. In this way it is possible to allocate the sample vessels to the analysis modules more efficiently.

As detailed above, are in accordance with the invention a large number of analysis modules in series or in parallel  arranged in the analyzer and are at least two Pro Bengefäßverteiler upstream and downstream of the analysis modules available. The sample vessel is upstream from the modules arranged distributor selectively on one of the analysis modules delivers, depending on the components of the sample to be analyzed, if necessary, the sample vessel to the first distributor is returned to the other module in an efficient manner to be analyzed. Since the distributor is a sample vessel Analysis module does not feed if the sample does not analyze there must be siert, the process capacity of the analyzer remarkably improved as a whole.

In all of the above-mentioned embodiments, the conveyors Devices for the sample vessels as a conventional sample be designed feeders, such as a conveyor belt, the Sample vessel distributor designed in the form of a gate mechanism can be. The analysis module itself is also known to the person skilled in the art known. For this reason, the exact construction of the Sample vessel feed, the distributor and the analysis module in this description is not explained.

Claims (10)

1. Automatic analyzer with a feed device for the successive feeding of sample vessels, which contain the samples to be analyzed, and a multitude of analysis modules, each of which can analyze at least one analysis object and has a sample delivery device for delivering samples into reaction vessels , characterized by
a plurality of first paths ( 6 , 9 ), on the central part of which an analysis module ( 1 , 2 ) is arranged;
at least one second path ( 7 , 10 ) which bypasses at least one analyzer module ( 1 , 2 ); and
a device for controlling the dispensing of the sample vessels so that each sample vessel to be guided by the sample vessel supply device ( 5 , 9 ) is selectively delivered either to one of the first routes ( 6 , 9 ) or the second route ( 7 , 10 ). 2. Automatic analyzer according to claim 1, characterized in that the plurality of first paths ( 6 , 9 ), each with an attached analysis module ( 1 , 2 ) is arranged in series with each other and each of a plurality of bypasses ( 7 , 10 ) in parallel to the respective first paths ( 6 , 9 ). 3. Automatic analyzer according to claim 2, characterized in that the control device comprises a plurality of sample vessel distributors ( 5 , 8 ), each of which in each case at a crossing point between the respective bypass ( 7 , 10 ) and a current on the end of the respective first route ( 6 , 9 ) is arranged, whereby the sample vessels are selectively assigned to either a by pass ( 7 , 10 ) or a first route ( 6 , 9 ). 4. Automatic analyzer according to claim 2, characterized in that at least one of the analysis modules ( 1 , 2 ) comprises a plurality of sub-modules ( 21 A , 21 B ) and the first way, which includes the rele vante analysis module, a variety of Sub-routes ( 25 A , 25 B ), in each of which one of the sub-modules ( 21 A , 21 B ) is arranged. 5. Automatic analyzer according to claim 1, characterized in that the plurality of first paths ( 38 , 39 ) with the related ver analysis modules ( 31 , 32 ) are arranged parallel to each other and form a parallel arrangement of analysis modules ( 31 , 32 ) A single bypass ( 43 ) is provided parallel to the parallel arrangement of the analysis modules ( 31 , 32 ). 6. Automatic analyzer according to claim 5, characterized in that the control device has a first sample vessel distributor ( 37 ) at a crossing point between an upstream end of the parallel arrangement of the analysis modules ( 31 , 32 ) and the bypass ( 43 ) for the selective distribution of the sample vessels in one of the plurality of first paths ( 38 , 39 ), and a second sample vessel distributor ( 41 ) at a crossing point between the downstream end of the parallel arrangement of the analysis modules ( 31 , 32 ) and the bypass ( 43 ) for the selective supply of the Sample vessels in the bypass ( 43 ) or a sample vessel receiver ( 44 ) for receiving the sample vessels with the samples, which have been delivered to the analysis modules ( 31 , 32 ). 7. Automatic analyzer according to claim 5, characterized, that each of the first ways has a variety of sub-ways, each between adjacent first routes at their upstream and downstream ends, and the control device continues to be a variety of sub-distributors, each arranged at intersections of the sub-paths. 8. Automatic analyzer according to Anspluch 1, characterized in that the plurality of analysis modules ( 1 , 2 ) are designed so that they can analyze different analysis objects from each other. 9. Automatic analyzer according to claim 1, characterized in that the plurality of analysis modules ( 1 , 2 ) are designed so that they can analyze the same analysis objects. 10. Automatic analysis device according to claim 1, characterized in that the plurality of analysis modules ( 1 , 2 ) are designed so that the analysis objects partially differ from each other.